Greece, a country characterised by intense seismic and volcanic activity, has a complex geodynamic and geological setting that favours the occurrence of many gas manifestations. In this study, we address the origin of CH4and light hydrocarbons in cold and thermal emissions discharging along the Hellenic territory. Also, we investigate their possible relationship with the main geochemical composition of the gases and the different geological settings of the sampling sites. For this purpose we collected 101 new samples that were analysed for their chemical (O2, N2, CH4, CO2, He, Ne, Ar, H2, H2S and C2-C6hydrocarbons) and isotopic (R/RA, δ13C-CO2, δ13C-CH4and δ2H-CH4) composition. Results show that CH4presents a wide range of concentrations (from <0.5 to 925,200 μmol/mol) and isotopic values (δ13C-CH4from -79.8 to +45.0‰ vs. V-PDB; δ2H-CH4from -311 to +301‰ vs. V-SMOW). Greece was subdivided in four geologic units (External [EH] and Internal [IH] Hellenides, Hellenic Hinterland [HH] and active Volcanic Arc [VA]) and a decreasing CH4concentration from EH to HH was recognized, whereas CH4showed intermediate concentrations in VA. The CH4/(C2H6+ C3H8) ratios (from 1.5 to 93,200), coupled with CH4isotopic features, suggest that the light alkanes derive from different primary sources and are affected by secondary processes. An almost exclusive biotic, mainly microbial, origin of CH4can be attributed to EH gases. Cold gases at IH have mainly a thermogenic origin, although some gases connected to continental serpentinization may have an abiogenic origin. Methane in gases bubbling in thermal waters of IH, HH and VA and fumarolic gases of the VA seem to have an abiogenic origin, although their chemical and isotopic characteristics may have been produced by secondary oxidation of thermogenic CH4, a process that in some of the sampled gases causes extremely positive isotopic values (δ13C-CH4up to +45.0‰ vs. V-PDB and δ2H-CH4up to +301‰ vs. V-SMOW).

Daskalopoulou, K., Calabrese, S., Grassa, F., Kyriakopoulos, K., Parello, F., Tassi, F., et al. (2018). Origin of methane and light hydrocarbons in natural fluid emissions: A key study from Greece. CHEMICAL GEOLOGY, 479, 286-301 [10.1016/j.chemgeo.2018.01.027].

Origin of methane and light hydrocarbons in natural fluid emissions: A key study from Greece

Daskalopoulou, Kyriaki;Calabrese, Sergio;Grassa, Fausto;Parello, Francesco;
2018-01-01

Abstract

Greece, a country characterised by intense seismic and volcanic activity, has a complex geodynamic and geological setting that favours the occurrence of many gas manifestations. In this study, we address the origin of CH4and light hydrocarbons in cold and thermal emissions discharging along the Hellenic territory. Also, we investigate their possible relationship with the main geochemical composition of the gases and the different geological settings of the sampling sites. For this purpose we collected 101 new samples that were analysed for their chemical (O2, N2, CH4, CO2, He, Ne, Ar, H2, H2S and C2-C6hydrocarbons) and isotopic (R/RA, δ13C-CO2, δ13C-CH4and δ2H-CH4) composition. Results show that CH4presents a wide range of concentrations (from <0.5 to 925,200 μmol/mol) and isotopic values (δ13C-CH4from -79.8 to +45.0‰ vs. V-PDB; δ2H-CH4from -311 to +301‰ vs. V-SMOW). Greece was subdivided in four geologic units (External [EH] and Internal [IH] Hellenides, Hellenic Hinterland [HH] and active Volcanic Arc [VA]) and a decreasing CH4concentration from EH to HH was recognized, whereas CH4showed intermediate concentrations in VA. The CH4/(C2H6+ C3H8) ratios (from 1.5 to 93,200), coupled with CH4isotopic features, suggest that the light alkanes derive from different primary sources and are affected by secondary processes. An almost exclusive biotic, mainly microbial, origin of CH4can be attributed to EH gases. Cold gases at IH have mainly a thermogenic origin, although some gases connected to continental serpentinization may have an abiogenic origin. Methane in gases bubbling in thermal waters of IH, HH and VA and fumarolic gases of the VA seem to have an abiogenic origin, although their chemical and isotopic characteristics may have been produced by secondary oxidation of thermogenic CH4, a process that in some of the sampled gases causes extremely positive isotopic values (δ13C-CH4up to +45.0‰ vs. V-PDB and δ2H-CH4up to +301‰ vs. V-SMOW).
2018
Daskalopoulou, K., Calabrese, S., Grassa, F., Kyriakopoulos, K., Parello, F., Tassi, F., et al. (2018). Origin of methane and light hydrocarbons in natural fluid emissions: A key study from Greece. CHEMICAL GEOLOGY, 479, 286-301 [10.1016/j.chemgeo.2018.01.027].
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/10447/278767
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